Tight closure with respect to a multiplicatively closed subset of an $F$-pure local ring (1301.6890v1)

Abstract: Let $R$ be a (commutative Noetherian) local ring of prime characteristic that is $F$-pure. This paper studies a certain finite set ${\mathcal I}$ of radical ideals of $R$ that is naturally defined by the injective envelope of the simple $R$-module. This set ${\mathcal I}$ contains $0$ and $R$, and is closed under taking primary components. For a multiplicatively closed subset $S$ of $R$, the concept of tight closure with respect to $S$, or $S$-tight closure, is discussed, together with associated concepts of $S$-test element and $S$-test ideal. It is shown that an ideal of $R$ belongs to ${\mathcal I}$ if and only if it is the $S'$-test ideal of $R$ for some multiplicatively closed subset $S'$ of $R$. When $R$ is complete, ${\mathcal I}$ is also `closed under taking test ideals', in the following sense: for each proper ideal $C$ in ${\mathcal I}$, it turns out that $R/C$ is again $F$-pure, and if $J$ and $K$ are the unique ideals of $R$ that contain $C$ and are such that $J/C$ is the (tight closure) test ideal of $R/C$ and $K/C$ is the big test ideal of $R/C$, then both $J$ and $K$ belong to ${\mathcal I}$. The paper ends with several examples.